Triazine derivatives and compositions thereof

ABSTRACT

TRIAZINE DERIVATIVES REPRESENTED BY ANY ONE OF THE FOLLOWING FORMULAE:   ((2-(R6-A2-),4-(R5-A1-)-S-TRIAZIN-6-YL)-NH-R3-COO(-))X (M)Y   (2-(R5-A1-),4,6-DI((-)OOC-R3-NH-)-S-TRIAZINE (M)Y   R5-(6-((-)OOC-R3-NH-)-S-TRIAZIN-2,4-YLENE)PX-R5 (M)PY   WHEREIN, A1 AND A2 ARE SAME OR DIFFERENT AND EACH DENOTES A POLYALKYLENE OXIDE SELECTED FROM THE GROUP CONSISTING OF POLYETHYLENE OXIDE   -(O-CH2-CH2)N-   POLYPROPYLENE OXIDE   -(O-CH(-CH3)-CH2)N-   AND POLYETHYLENE OXIDE-POLYPROPYLENE OXIDE COPOLYMER   -(O-CH2-CH2)M- -(O-CH(-CH3)-CH2)N   WHEREIN N IS AN INTEGER OF 1 TO 200 AND M+N IS AN INTEGER OF 2 TO 200 (M AND N$1); R3 AND R4 ARE SAME OR DIFFERENT AND EACH DENOTES A MEMBER SELECTED FROM THE GROUP CONSISTING OF ALKYLENE OF 1 TO 12 CARBON ATOMS, O- AND PCYCLOHEXYLENE, O- AND P-METHYLENE CYCLOHEXYLENE, O- AND P-PHENYLENE, AND O- AND P-METHYLENE PHENYLENE; M DENOTES A MEMBER SELECTED FROM THE GROUP CONSISTING OF HYDROGEN, A METAL SELECTED FROM THE GROUP CONSISTING OF CALCIUM, BARIUM, MAGNESIUM, TIN, ALUMINUM, COPPER, POTASSIUM, SODIUM, ZINC, MANGANESE, NICKEL, STRONTIUM AND CADMIUM, AND AN ORGANIC AMINE SELECTED FROM THE GROUP CONSISTING OF MONO-, DI- AND TRI-ETHANOL AMINES, AND PRIMARY, SECONDARY AND TERTIARY AMINES OF 1 TO 17 CARBON ATOMS; X AND Y EACH DENOTES AN INTEGER OF 1 TO 4 DEPENDING ON THE VALENCY OF THE METAL; P IS AN INTEGER OF 2 TO 5; AND R5 AND R6 ARE SAME OR DIFFERENT AND EACH DENOTES A MEMBER SELECTED FROM THE GROUP CONSISTING OF HYDROXY, ALKOXY OF 1 TO 10 CARBON ATOMS, NAPHTHOXY, BENZOXY, SECONDARY AMINO OF 1 TO 17 CARBON ATOMS, AND   -OOC-R7   WHEREIN R7 DENOTES A MEMBER SELECTED FROM THE GROUP CONSISTING OF ALKYL OF 1 TO 17 CARBON ATOMS, PHENYL, PCARBOXY PHENYL   4-(HOOC-)PHENYL   AND NAPHTHYL PREPARED BY ALCOHOL INTERCHANGE REACTION BETWEEN SODIUM OR POTASSIUM SALT OF DI-(OR MONO) ALKOXYMONO- (OR DI-RESPECTIVELY)-W-AMINOACID-SYN-TRIAZINE AND POLYALKYLENE GLYCOL OR DERIVATIVE THEREOF, ARE SUPERIOR ANTISTATIC AGENTS FOR POLYMER MATERIALS SUCH AS POLYAMIDES, POLYESTERS, POLYOLEFINES, POLYSTYRENE, POLYVINYL CHLORIDE, POLYVINLIDENE CHLORIDE, POLYMETHYLMETHACRYLATE, POLYACRYLONITRILE BUTADIENE STYRENE TERPOLYMER.

TRIAZINE DERIVATIVES AND COMPOSITIONS THEREOF Filed Aug. 28, 196e 0d. 24, 1972 TA1-suo lsHmAwA EVAL 9 Sheets-Sheet 1 s m M mv w w m N a u m M 4 m w@ wm M n :-Eemmnzw? I a l OO@ OG O OO OOQ OO: O@ OO@ OOS OO@ OG Q OOC OO@ OO@ OO1ON DOWN OON OONm OOwm O W o um ik haw Q N U o M Nm wmf.. om f\ om/\/ om d ht Y ofN b Q m N .MO B i S i E? m n: x c w tl/f\\ w m ,m w mmm Q N N m m mm Q Q N @nim a Q 3; Q m m* NF Z O 0.@ O. ON O. m Ow Om Oct. 24, 1972 TATsuo lsHlKAwA Erm. 3,700,662

TRIAZINE DERIVATIVES AND COMPOSITIONS THEREOF NOISSI WSNVHJ. LNBOEd atsu kmq, sham www, INVENTORS Truoml Wakmboyashi, Yoshihiko Inamoto, Tesuhro Knnsuwwsel Tqtsuid uvnak,

and. Masami O- ATTORNEYS Oct. 24, 1972 TArsuo ISHIKAWA E'rAL 3,700,662

TRIAZI-NE DERIVATIVES AND COMPOSITIONS THEREOF Taisuo Ishikawa, Shiro Hind-c?, INVENTORS Teruom h/mkmbmyaskk, Yashiufw Ingmofo, Tntsuhx'ro Kusumosel Tq-Lsuchl Tsar-nain,

and. 010.54m" Ot BY wrwv/ @mw-16% ATTORNEY S Oct. 24, 1972 rATsUo ISHIKAWA ETAL 3,70,662

TRIAZINE DERIVATIVES AND COMPOSITIONS THEREOF Tqisuo Ishkcw-n, Shiva Hiruin, INVENTORS'- Teruom'l Wake; bayash/ Yoshhiko Tnarnot, Tetsuhif KuSunOse ,Toisuicki Tsurncnki,

ATTORNEYS Oct. 24, 19,72 3,700,662

TRIAZINE DERIVATIVES AND COMPOSITIONS THEREOF Filed Aug. 2e. 196e TATSUO ISHIKAWA ETAL 9 Sheets-Sheet :h mmnzm www@ N .Jr

ha W .mlm MU H u OQ r MM m Inh@ H @www H. f YR Ubu amsn

mak

SUO. w I fwm o m ln a u o u s TRIAZINE DERIVATIVES AND coMPosITIoNs THEREOF Filed Aug. 28, 1968 Oct. 24, 1972 TATsuo lsHlKAwA ETAL 9 Sheets-Sheet 6 .Ee mmnzm OO@ Ooh oo Oom OOQ Oo: Oog oo@ O91 OO@ COQ ooi OO@ Oo@ ooow @ovm oom 00mm comm OOO@ o J Y Q 7 o N M i 3 2 f o m m v f Q N 5P) m Y w o o c f W T (k\ s 1 mm- N O* Om Om Oh O Om Ov Om m0 1 1525MB? w .O n.

INVENTORS ncxrnoie/ ATT( )NN'YS Tqisuo Ishikawa, Shia-o Hiram, Teruomi v/kqbcyashg ashamko Te Byrwaw/@m/Lqf TRIAZINE DERIVATIVES AND coMPosmIoNs THEREOF Filed Aug. 28. 1968 Oct. 24, 1972 TATsuo lsHlKAwA ETAL 9 Sheets-Sheet 7 m www n m m im Cw/O W of a, om@ m a ...M M -eemmznzm Tn. Tw OOO OO OO OO@ OOO* OO: OON. OO@ OO OOm OO OOC OO@ OO@ OOON OOQN OON OONm OOOm OOOQ um .l 1w. 4m Dwr N N o N M m WT@ b o, M W f www a a M Nvmwmm m Mmmm O N g; m- .M N I Ov 0.@ O. OH O O.m Od O.m m10. 3 T Szmd? N .O m

Oct. 24, 1972 'rA'rsUo lsHlKAwA ETAL 3,7005552 TRIAZINE DERIVATIVES AND COMPOSITIONS THEREOF Filed Aug. 28, 1968 9 Sheets-Sheet 8 ATTORNEYS and Masami Otu.

Oct. 24, 1972 TATsUo lsHlKAwA ETAL 3,700,662

TRIAZINE DERIVATIVES AND COMPOSITIONS THEREOF NOISSI WSNVELL .LNlOtEd INVENTORS "lztsuo Tslmknwu/ Shiro Hrufa., Teruom Wakaba ash', Yoshihko lnqmoto Tetsuhro KusunOSe, Tqtsuioh 'IZ-.n.vmmkil Quel Masami Otn BY: @Maxam/W.;

ATTORNEYS United States Patent O M' 3,700,662 TRIAZINE DERIVATIVES AND COMPOSITIONS THEREF Tatsuo Ishikawa, 6-3 Kitashinkoj; Shiro Hiruta, 4770 Yamatsukicho; Teruomi Wakabayashi, 1 Sakurazonocho; Yoshihiko Inamoto, 3-1 Nakagawaracho-Z-chome; Tetsuhiro Kusunose, 4850 Nakagawaracho-Z-chome; Tatsuichi Tsumaki, 4920 Nakagawarach-Z-chome; and Masami Ota, 4993-374 Shmonagahamacho, all of Nobeokashi, Japan Filed Aug. 28, 1968, Ser. No. 755,875 Int. Cl. C07d 55/18, 55/20 U.S. Cl. 260-242 4 Claims ABSTRACT F THE DISCLOSURE Triazine derivatives represented by any one of the following formulae:

wherein, A1 and A2 are same or different and each denotes a polyalkylene oxide selected from the group consisting of and polyethylene oxide-polypropylene oxide copolymer wherein n is an integer o-f 1 to 200 and m-l-n is an integer of 2 to 200 (m and nl); R3 and R4 are same or different and each denotes a member selected from the group consisting of alkylene of 1 to 12 carbon atoms, oand pcyclohexylene, oand p-methylene cyclohexylene, oand p-phenylene, and oand p-methylene phenylene; M denotes a member selected from the group consisting of hydrogen, a metal selected from the group consisting of calcium, barium, magnesium, tin, aluminum, copper, potassium sodium, zinc, manganese, nickel, strontium and cadmium, and an organic amine selected from the group consisting of mono, diand tri-ethanol amines, and primary, secondary and tertiary amines of 1 to 17 carbon atoms; x and y each denotes an integer of 1 to 4 depending on the valency of the metal; p is an integer of 2 to 5; and R5 and Re are same or different and each denotes a member selected from the group consisting of hydroxy, alkoxy of 1 to 10 carbon atoms, naphthoxy, benzoxy, secondary amino of 1 to 17 carbon atoms, and

3,700,662 Patented Oct. 24, 1972 ICC wherein R, denotes a member selected from the group consisting of alkyl of 1 to 17 carbon atoms, phenyl, p-

carboxy phenyl This invention relates to novel triazine compounds and a method for preparing the same.

Further, this invention relates to compositions containing said novel compounds which are characterized by their improved antistaticity.

The novel compounds of the present invention are triazine derivatives represented by any one of the following formulae:

N H N n mar- TMR, oooRlN-f -Nmooo I My; L M! IllHRaCOO x and J RsLVN-Ar-j-Rt N iv M" llIHRiCOO px wherein, A1 and A2 are same or different and each denotes a polyalkylene oxide selected from the group consisting of polyethylene oxide polypropylene oxide polyethylene oxide-polypropylene oxide copolymer wherein n is an integer of 1 to 200 and m-I-n is an integer of 2 to 200 (m and nl); R3 and R4 are same or different and each denotes a member selected from the group consisting of alkylene of 1 to 12 carbon atoms, oand pcyclohexylene, oand p-methylene cyclohexylene, oand p-phenylene, and oand p-methylene phenylene; M denotes a member selected from the group consisting of hydrogen, a metal selected from the group consisting of calcium, barium, magnesium, tin, aluminum, copper, potassium, sodium, zinc, manganese, nickel, strontium and cadmium, and an organic amine selected from the group consisting of mono, diand tri-ethanol amines, and primary, secondary and tertiary amines of 1 to 17 carbon atoms; x and y each denotes an integer of 1 to 4 depending on the valency of the metal; p is an integer of 2 to 5; and R5 and Re are same or different and each denotes a wherein R7 denotes a member selected from the group consisting of alkyl of 1 to 17 carbon atoms, phenyl, p-carboxy phenyl and naphthyl.

The novel compound as identified above can be advantageously used as antistatic agents for synthetic polymers such as polyamides, polyesters, polyolefins, polystyrene and polyvinyl chloride, said antistatic effect being imparted by incorporating the triazine derivative in a conventional manner with such synthetic polymers as mentioned above. Single compound or the mixtures of two or more triazine compounds are used.

Generally, the buildup of high electrostatic charges on the synthetic polymer materials, formed by contact and friction thereof with other materials, causes various troubles in the fabricating operations and in the use, such as attracting clust and sparking, etc.

Especially, this is remarkable in the atmosphere of low humidity, i.e. lower than 50% of relative humidity (abbreviated as RH hereafter). For example, contact of polyamide fibers with other materials creates high electrostatic charges on the fibers, which causes repelling motion between individual filaments and fluff in textile processing and unpleasant shocks to human bodies.

These undesirable phenomena are considered to be due to the staticity of the synthetic polymer materials.

In order to suppress the staticity of the synthetic polymer materials or to substantially eliminate the staticity, various antistatic agents have been heretofore proposed.

For example, it is well-known to apply them on the surfaces of the materials, as described in American Dye- 4 stuff Reporter, 41 368 (1954) or to melt-mix them into the material, as described in British Pat. No. 907,016 and in British Pat. No. 963,320.

Most of the existing antistatic agents, however, have proved to be deficient in practical use in that the antistatic effect soon decays and that the presence of the antistatic agents with the synthetic polymer material tends to cause the breaking of threads during spinning and drawing operations and, the yellowing of articles as molded, which results in lowering of the operational efficiency and the degradation of the products.

The novel compounds according to the present invention are especially useful as antistatic agents when they are admixed with the synthetic polymer materials.

Further, the compounds of the present invention are advantageously added to the synthetic polymer materials since they remain stable up to about 300 C., and up to C. even on heating treatment in the presence of oxygen.

They are effective through the conventional applying procedures such as melt-mixing, coating and dipping.

One object of the present invention is to provide novel compounds which have a desirable affinity to and compatibility with the various synthetic polymer materials and are esecially suitable as antistatic agents for them, and are assured to be effective even Where the polymers are subjected to extraction, dyeing and laundry procedures under sever conditions.

A further object of the present invention is to provide superior antistatic agents which are free from those deficiencies encountered in the use of conventional antistatic agents, i.e., loss of operational efficiency and degradation of the products, such as lowering of spinning efficiency due to end breakage and fluff and molding eiciency and yellowing of the molded articles due to the insufficient feedability of the polymer material into the screw-type extruder, which has ordinary formed a source of troubles when the known antistatic agents were melt-mixed in the polymer material.

A further object of the present invention is to provide a method for preparing the novel triazine derivatives.

Still further objects of the present invention are to provide polymer compositions which exhibit substantial antistaticity even in an atmosphere of a low humidity.

The whole scheme for producing the novel compounds of the present invention is illustrated in the following equations:

N N N E TR mi TR n Brt TR' l l N\/N HzNRaC O OH N\/N Na+ N\/N I C1 INRiCOOH liiNRaCOONa (I) (Il) (11) HOAlR; HOAzRa N N RsAr- -AzR RiAi f AzRs I N\/N N N My HOA1R| HNRzCOONe HNRzCOO x (V)) Cation Exchange Resin Organic Amine or (V1) Chloride N N Re I I lRl R5 I Ai I R5 N N N M p Cation Exchan e p' Resin Organgic Ell Amine NRgCOONa i Chloride NHRzC O O ipx N N N cl- Tol HoocRtNH'f/ Tumaco on Nao ooRtNH- HNRlco oNa L HzNR CO OH N lq' N -l- N |N l mNmco on l l R1 Rl R1 (VII) (VIII) (VIII) ,/tion Exchange Resin Organic Amine or N OOCHNH {NHNRICOO N\/N My lRs X wherein R1 and R2 are the same or different and each denotes an alkoxy group of 1 to 4 carbon atoms, R3, R4, R5 and R6 are defined before and M, p, x and y are as defined before: Although there is no reference to the potassium salt in the above formulae for simplification, the potassium salt is included in the same manner as above.

Referring to the above formulae; the method of the present invention is now explained in detail.

Di (or mono-)alkoxy mono-(or direspectively) chloro syn triazine (I) or (VII) respectively is reacted with an w-amino acid in a homogeneous phase in an appropriate solvent such as water, methanol, ethanol, propanol, butanol, or mixtures of at least two of them. The presence of an alkaline condensating agent such as sodium bicarbonate, sodium hydroxide, sodium carbo nate, potassium bicarbonate, potassium carbonate, or potassium hydroxide in the reaction system is effective in promoting the reaction. Thus obtained is, the sodium or potassium salt (II) or (VIII) of di-(or mono) alkoxy mono- (or di-respectively) w aminoacid syntriazine (II) or (VIII) respectively, which is then reacted With one or more polyalkylene glycols or the derivatives thereof to form compound (III), (V) or (IX) by alcohol interchange reaction. In order to obtain the metal salts of compound (III), (V) or (IX) other than sodium salt and potassium salt, compound (III), (V) or (IX) is reacted with chloride to complete metathesis, giving finally compound (IV), (VI) or (X) respectively. A1- ternatively, in order to obtain amine salts of compounds (III), (V) or ('IX), the compound (III), (V) or (IX) is treated with cation exchange resin, followed by the neutralization treatment with organic amines, to give finally compounds (IV), (VI) or (X) respectively. When, M is hydrogen, the amination process or metathesis is eliminated. Di-(or mono-)alkoxy mono-(or di) chlorosyn triazine (I) or (VII) is generally prepared by the reaction between cyanuric chloride and a lower alcohol such as methanol, ethanol, propanol, n-butanol, isobutanol, as reported by James R. Dudley in J. Am. Chem. Soc. 1951, 73 p. 2986.

On the metathesis reaction, although any metal ion may be used as cation so long as the addition of metal ionsdoes not seriously cause undesirable yellowing of synthetic polymer material, those appropriate are calcium, barium, magnesium, tin, aluminium, copper, potassium, sodium, zinc, manganese, strontium, cadmium and nickel.

Chloride A1 and A2 of the compounds (IV) and (VI), are same or different and each denotes polyalkylene oxide selected from the group consisting of polyethylene oxide polypropylene oxide or polyethylene oxide-polypropylene oxide copolymer wherein n is an integer of 1 to 200 and nul-nA is au integer of 2 to 200, (m, nl).

As said polyalkylene glycol derivatives, there may be mentioned compounds prepared by etherifying one of the hydroxy groups of the polyalkylene glycol with an alkyl group of 1 to 10 carbon atoms such as, methyl, ethyl, propyl, iso-octyl, or decyl, or with an aryl group such as nonylphenyl, dodecylphenyl, phenyl, or naphthyl, and compounds prepared by esterifying one of the hydroxy groups-with an aliphatic carboxylic acid of 1 to 18 carbon atoms such as formic acid, acetic acid, stearic acid, lauric acid, propionic acid, caproic acid, or aryl carboxylic acid such as benzoic acid, naphthoic acid, or terephthalic acid, and compounds prepared by aminating one of' the hydroxy groups of polyalkylene glycol with a secondary amine of 1 to 17 carbon atoms such as dimethylamine, diethylamine, dipropylamine, dioctylamine, dilaurylamine, distearylamine, methylethylamine, methylpropylamine, methyloctylamine, ethyllaurylamine, diphenylamine, or ethylphenyl amine.

The illustrative examples of organic amines used in the neutralization process include ethanolamines such as monoethanolamine, diethanolamine or tethanolamine, primary, secondary and tertiary amines of 1 to 17 carbon atoms per chain such as methylamine, ethylamine, propylamine, stearylamine, caprylamine, cyclohexylamine, dimethyla'mine, diethylamine, dipropylamine, diisopropylamine, dicaprylamine, ethylstearylamine, ethylcyclohexylamine, trimethylamine, triethylamine, tripropylamine, triiisopropylamine, methylethylamine, methylpropylamine, methyl-i-propylamine, stearylcaprylamine, methyllaurylamine, ethylpropylamine, ethyl i propylamine, ethyllaurylamine, methyloctylamine, diphenylamine, ethylphenylamine, dimethylethylamine, dimethylpropylamine, dimethyl-i-propylamine, dimethylstearylamine, methylethylpropylamine, methyldipropylamne, diethyllaurylamine, methylethylcyclohexylamine, diethylcaprilamine, dimethyllaurylamine, or ethylpropylstearylamine.

As said R3 and R4 there may be mentioned methylene, ethylene, trimethylene, pentamethylene, hexamethylene, octamethylene, decamethylene, undecamethylene, o-cyclohexylene, p-cyclohexylene, o-methylene cyclohexylene p-methylene cyclohexylene, o-phenylene, p-phenylene, omethylene phenylene, or p-methylene phenylene.

According to the present invention, the polymer compositions free from staticity are obtained by adding at least one triazine derivative as specified above to any synthetic polymer materials. Although these compounds (IV), (VI) and (X) may be added to the polymer materials in interest at any time during the manufacturing process to impart permanent antistatic effect to them, the addition of the compounds to the polymer material in the polymerization process and in the molding process results in imparting to the polymer material more permanent antistatic effect.

The illustrative polymer materials to which the compounds of the present invention are added include homoand co-polyamides such as nylon 6, nylon 6.6, nylon 6,10, nylon l1, nylon 3, nylon 4, nylon 7, nylon 9, nylon 6, nylon l2, nylon /metaxylenediamine, nylon `6/ 6.6, nylon 6/ 6.10, nylon /hexamethylene terephthalamide, 6- metaxylylenene adipamide, 6/6.6hexymethylene terephthalamide, nylon 6/6./metaxylyleneadipamide; polyesters such as polyethylene terephthalate, polycyclohexylene dimethylene terephthalate, polyester from vanilic acid, polycarbonate, polyethylene isophthalate; polyoleines such as polyethylene, polypropylene; polystyrene; polyvinyl chloride; polyvinylydene chloride; polymethylmethacrylate and polyacrylonitrile-butadiene-styrene terpolymers.

The amount of the compounds to be added to the polymer material is determined at such value as not to cause undesirable effect on the spinnability and moldability of the polymer material. Therefore, amounts ranging from 0.1- percent by weight based on the polymer amount is employed with good spinnability, moldability and compatibility.

Amounts above about 20 percent by weight will result in poor spinnability, and poor moldability. The lower limit for the amount is determined by consideration of the effects to be desired.

The compounds of the present invention may be used in conjunction with other additives, such as plasticizers, color-stabilizers, thermal stabilizers, U.V. absorbants, dyes, and/or pigments.

The compounds of the present invention are advantageously utilized as antistatic agent for the polymer material.

It is noted that the antistatic effect of the compositions of the present invention is markedly superior to that imparted by the conventional antistatic agents, as shown in the illustrative examples. Further, said eect has proved to last through washing.

Antistatic effect is represented by half-life period of the static charge voltage.

Measurement of the half-life period is made as follows.

10,000 v. is applied to the sample for 3 minutes at 20 C. in 40i3% RH and then the applied voltage was cut, at which time the measurement of the static charge voltage of the sample is started and is kept until the statistic charge voltage is reduced to half as much as that at the beginning. This time duration is taken as half-life period.

The sample prepared from the composition comprising polymer material and at least one compound of the present invention as an antistatic agent exhibits the half-life period of less than 5 seconds, while the conventional polymer compositions exhibit half lives of more than 300 seconds.

FIGS. 1 through 9 illustrate infrared spectra for the triazine derivatives obtained according to the present invention.

The following examples are intended to be illustrative only and not to be considered as exclusive.

`In each example, the important compounds are aecompanied by the structural formula number for reference.

EXAMPLE 1 Preparation of 2,4-dimethoxy-6-amino-caproic acid-syn-triazine 2,4 dimethoxy 6 chloro syn triazine (70.2 g.) and e-amino caproic acid (65.6 g.) were added with stirring into water (500 ml.) at room temperature to which was further added sodium bicarbonate (42.0 g.) to form the mixture solution.

Then the mixture solution was heated at 75-80" C. with stirring for 2 hours.

It was then cooled and white crystals (78.0 g.) of 2,4- dimethoxy--amino caproic acid-syn-triazine, having a melting point of 126-128 C., which is represented by the structural Formula II (referred to as compound (II) hereafter) were obtained.

Elemental analysis of compound (II). Calcd.: (percent): C, 47.7; H, 6.8; N, 20.3. Found (percent): C, 48.8; H, 6.6; N, 20.7.

Infrared spectrum of compound (II) is shown in FIG. 1.

Polyethylene glycol (molecular weight 1500) (300 g.) was dried at 120 C. in vacuo, to which was added and dissolved 8 mol percent of metallic sodium.

To this solution was added the sodium salt (29.0 g.) of 2,4-dimethoxy-6-amino-caproic acid-Syn-triazine obtained as above. The resulting mixture was heated with stirring rst for 2 hours at 90 C., under a pressure of 2O mm. Hg and then for 2 hours at 150 C. under a pressure of 2 mm. Hg.

The elution of methanol which was considered to be caused by the alcohol interchange reaction was observed.

After cooling there was obtained a light-yellow waxy material corresponding to the structural Formula V.

The aqueous solution of the light-yellow waxy material was then treated with cation exchange resins (Dowex 50W-X8) and condensed, giving 270 g. of material corresponding to the structural Formula VI.

N nozniom-f Mrocznmton NH(CHz)COONa (V) EXAMPLE 2 The white waxy material of structural Formula VI g.) obtained in Example 1 was neutralized with diethanolamine (30 g.), giving corresponding diethanol amine salt 9 (91 g.) in 90% yields, the infrared spectrum of which is represented in FIG. 5.

N HowzHlom- -(ooznouon CZHOH n, simon Nmonmcoo (VI) EXAMPLE 3 The light yellow waxy material of the structural Formula V (100 g.) obtained in Example 1 was metathesized with 20% aqueous solution of barium chloride (30 g.) The resulting solution was condensed under a reduced pressure, by produced sodium chloride removed by extraction with toluene.

Infrared spectrum for the barium salt (VI) is given in FIG. 4.

N Homomw/ l-(Oclmmou NH(CH2)ACOO 2 EXAMPLE 4 2 methoxy 4,6 dichloro syn triazine (72.0 g.) and e-amino caproic acid (66.0 g.) were dispersed in water (800 mL), to which was added sodium hydroxide (20 g.). The resulting mixture was heated for 2 hours at 80 C., then cooled to give white crystals in 73% yield. There was thus obtained 2-methoxy-4,6diamino caproic acidsyn-triazine (VIII) having a melting point of 182-184" C.

Elemental analysis of the compound (VIII). Calcd. (percent): C, 52.0; H, 73.0; N, 19.0. Found (percent): C, 52.7; H, 71.0; N, 20.9.

The sodium salt (VIII) of 2-methoxy-4,6diamne caproic acid-syn-trazine was reacted with polyethylene-glycol (molecular weight 1000) in the same manner as described in the Example 1 and then treated with ion exchange resin, giving light brown waxy material (X). The infrared spectrum of the material (X) is given in FIG. 6.

EXAMPLE 5 A variety of triazine derivatives were prepared in the same manner as described in Examples 1 to 4 and illustrated in Table 1. Infrared spectra for compounds obtained in Run Nos. 16, 3 and 13 are shown in FIGS. 7, 8 and 9 respectively.

TABLE 1 Structural Formula (IV) (VI) (X) M.P. C.) M X Y (11) or (V III) m+n Mole orn ratio'l Yield mur' Run No.

7----.--... -OCHa 0CH;

-O CH3 -0 CNH ZI.. H H m l NH .N HN N w L Ho @I .mHHooooI Q I Imool .mool n H H m I l S N .o S I Ho mol I mol I Lomool .mool I H H m NNH. N .HHH NN N SH LSSI mol mol I Iomool mool I H H m SS N.NH S N SH .InHonHHIeHo Hol mol mol I IHHmoT mooI o o ol l H H m SS N .NH S H SH I Ho mol I Imovl Lomool I LmHooI :NN I H N No I I S H NN L Ho HHHI I mol .O IOI I .mool :HN I H N Nm I N .N NN H NN Io Hol I mol Lomovl Imool I mool .-.NN I H N HQ HYS I S N SH Ilo mol mol mol l omool .mool mo oI ..-NH I H N Nm SN@ I S N S I Ho mol mol mol I movl mool mooI .--NH I H N .No SS I HN N S Iomol moI mol I mowl mooI mool ---.:WNH I H H Q I N .NH S N NN I Ho Hol mol mol l Imo I mo oI mo ol :NH I H H m I N .N S N NH H. I Homol mol mol I IHHHmool .mo ol mooi -..NH I H H m I N .N S N m Ixomvl .moool 0 I Imovl .mo ol .mooI ...NH .mo mo zl zI I H H m I NH .n NN N NH 1 InHomHl mo mo I Lomool .mooI .mo ol NH mooo|ool @loool I H H m NNN@ N.: S N SH H. I Homol I ImoHI .mooI mool -..NH I H H m NHIHN HzNH NN N SH H. InHoNoI mooool HHmoHoooI I Lomool .mo oI mool :HH Oll I H H m SIS N .HH S N SH H. I Ho NHT mol M l Lomool .mool .mo ol ---SH H N H H Ho o .H @HNS 2HE H o .HH .m .m m HHH Hm .oz Ham .NH2 28a :+S oc Fc So @No `HHHH V s .mo

NHHHHFHom HEHHNoHEm uoHHHHEHHoUIIH HAMAS..

o mmm m0 mo /z /z I H H m l NH n HH.. N 0H Icl .mo mo I :EOT wool l N No l l NN N om I Hml mol mHoI l movl wool I H H HMH I NN N Iimmvl mol mol l SHOT HHOOI I H N Nm I I NN N LHHT .mool .wool l :EOT mumool I H H m I I NN N E Ilol .wool mool I LHNNHQI mool H N No I I HN N HH.. I .HUHHT mol mol I LEHQI mol I H N Nm I I NN H NN I Hml I mHoI I ImOvl l H w N HH con i5 E05 BHS o HH m m um .H.H H 20E Qc HZ SC HUG oHHH .sbc

TABLE 2 Triazine derivative (V I) Di-ethanolamine salt of triazine Barium salt (Vl) of triazine (in Example l) derivative (VI) (in Example 2) derivative (in Example 3) Amount Tenacity Tenacity Tenacty added (g./denier)l Half-life (g./dem'er)/ Hali-life (g./denier)/ Half-life (Wt. Relative elongation period Relative elongation period Relative elongation period Run No. percent) viscosity (percent) (sec.) viscosity (percent) (sec.) viscosity e (percent) (sec.)

2. 94 6. 0/28 2. 94 6. 0/28 w 2. 94 6. 0/ 28 0. 2. 90 6. 1/24 20 2. 93 5. 7/25 23 2. 88 5. 9/30 18 1. 0 2. 87 5.9/26 9 2. 87 5. 7/26 8 2. 84 2. 7/29 8 3. 0 2. 7U 5. 8/25 2 2. 74 2. 9/26 3 2. 79 5.8/25 1 5. 0 2. 43 5. 0/26 1 2. 56 5. l.i/27 1 2. 60 5. 6/28 l 10. 0 2. 10 4. 1/23 1 2. 13 2. 9/27 1 2. 20 4. 2/24 1 l Relative viscosity Was measured at C. for polymer solution in 95.5% sulfuric acid at a concentration of 1g./100 ml.

equipped wtih a stirrer was charged with dry Ie-caprolactam TABLE 3 (2 kg.) together with water (0.3% by weight) as a cat- 20 alyst. The air was displaced from the autoclave with Washing times 5 10 30 50 nitrogen and sealed.

The reaction mixture was heated at 260 C. for 10 hours Half-life period (Sw) to complete polymerization, giving molten polymer. a, The triazine derivative Was injected into the molten 2g ig 2g 2g 25 polymer, which was then stirred vigorously for 1 hour in 2 3 2 1 nitrogen stream, and then taken out of the autoclave from 1 1 1 1 the bottom thereof. The amount of triazine added for each run is given in Table 5. The polymer obtained was melt spun into 210 deniere24 iilament yarn. The properties and EXAMPLE 7 30 antistatic eiect of the yarn are given in Table 5.

Five runs were made for each of the triazine derivatives prepared in Run Nos. 1, 16 and 27 of Example 5 as follows:

A 4 lit. autoclave equipped with a stirrer was charged with nylon 6.6 salt (15 kg.) and water (0.6 kg), to which 35 TABLE 5 triazine derivative was added at an amount listed in Table 4 belOW- Amount Te/cfiiil/ Hair-life The air was displaced from the autoclave with nitrogen, added (wt. .Relative elongation Period and the temperature of the reaction mixture was main- Run No' pement) viscosity n (pement) (Sem) tained for l hour at 230 C. under the pressure of 17.5 0 2. 92 6.?/20 14g/cm.2 and then, for another 2 hours at 270 C. under g2g g1g? g'. 1g the same pressure to complete polymerization. 3-0 2.81 5-9/25 2 The pressure was reduced to normal pressure in 2 hours 5' o 2'72 5'6/28 1 measured under the same condition as in and the reaction mixture heated for minutes. The re- Relative viscosity WBS sulting white polymer was taken out of the autoclave Table 2 from the bottom thereof and was formed into chips. There was thus obtained white nylon 66 chips.

The chips were spun into a 210 denier-24 filament yarn in the same manner as in Example 6.

The tenacity/elonation and antistatic eiect of the yarn EXAMPLE 9 are listed in Table 4, showing superior yarn properties and Three runs were repeated for triazine derivative preantistatic eect. pared in Run No. 1 of Example 5.

TABLE 4 Triazine derivative prepared Trlazine derivative prepared Triazine derivative prepared in Run No. 27 (in Example 5) in Run No. 16 (in Example 5) in Run No. 1 (in Example 6) Tenacity Tenacity Tenacity Amount (g./denier)/ Half-life (g./denier)/ Half-life (g./denier)/ Half-life added (Wt. Relative elongation period Relative elongation period Relative elongation period percent) viscosity (percent) (sec.) viscosity (percent) (sec.) viscosity (percent) (sec.)

0 2. 81 6. 2/25 w 2. 81 6. 2/25 m 2. 81 6. 2/ 25 w O. E 2. 76 6. 0/27 18 2. 77 6. 0/25 30 2. 80 6. 1/30 20 1. 0 2 69 5.7/27 7 2. 65 5. 8/27 l0 2. 70 5. 9/23 5 3. 0 2. 53 4. 9/26 2 2.60 5. (/29 3 2. 62 5. 8/24 2 5. 0 2. 37 4. 2/25 1 2. 52 5. 0/23 1 2. 55 5. l/27 l Relative viscosity was measured under the same condition as in Table 2.

EXAMPLE 8 Each run was made as follows:

Five runs were made for triazine derivative prepared in Nylon 6 Chips (full'dun) having relative VSCOSY 0f Run No. 28 of Eaxmple 5 as follows. An autoclave 75 2.30 was blended with the triazine derivative, then formed 17 into 40 denier-8 filament yarn by a conventional melt spinning process. The amount of the triazine derivative added in each run is given in Table 6.

TABLE 7 Triazine derivative prepared in Run No. 29 (in Example 6) Triazine derivative prepared in Run No. 30 (in Exzmple 5) Triazine derivative prepared in Run No. 3 (in Example 5) Tenacity Tenacity Tenacity Amount (g./denier)l Hall-hie (g./den1er)l Half life (g./denier)/ Halt-life added (wt. elongation period elongation period elongation peaiod Run No percent) (percent) (sec.) (percent) (sec.) (percent) (sec.)

The properties, the antistatic effect and the permanency TABLE 8 of the effect of the yarn are shown in Table 6, all proving 4 Amount of tnazine derivative added superior. 20 (wt. percent) TABLE 6 o 0.1 o. 5 1. o a. o 5. o

Amount Tenity Run No- Half-life period (see added (g./d.)/ Half-life Half-life (Wt. Relative elongation period 5 12 8 5 2 1 Run No percent) viscosity (percent) (sec.) 10 lo s 6 3 1 m 14 7 4 1 1 0 2. 30 5.2/31 w o. 5 2. 31 5. 1/33 2o 50 13 9 5 2 1 1. 0 2. 30 5. l/32 8 3. 0 2. 25 4. 2/30 2 Half-life period was measured for the sample yarn Washed 5 times. bHalf-life period was measured for the sample yarn dyed with an EXAMPLE 11 acidic dye (Commersie Sky-SE (0.1. Acid Blue 112); trademark) solution having the concentration of 0.3% by weight based on the weight ot the yarn at pH 4.0, at 95 C. for 90 minutes and then Washed with Water.

EXAMPLE 10 Seven runs were repeated on each of the compounds prepared in Run Nos. 3, 29 and 30 of Example 5. Each run was made as follows:

A 5 lit. autoclave equipped with a stirrer was charged with bis-hydroxyethyl-terephthalate (1.5 kg.), metallic sodium as an ester interchange catalyst and the triazine derivative. The amount of the triazine derivative added in each run is given in Table 8. Then the air was displaced from the autoclave with nitrogen, and the mixture was then heated at 270 C.-300 C. with vigorous stirring to complete polymerization, eluted ethylene glycol distilled off, while gradually reducing the pressure to 10-10-1 mm. Hg.

In each run, the polymer obtained was dried, melt spun at 280 C.-300 C. with a conventional melt-spinning apparatus and then drawn at the drawing ratio of 3 to 4 into a 210 denier-24 filament yarn. The antistatic effect as well as other physical properties of the yarn are given in Table 7.

In order to demonstrate the permanency of the antistatic eiect, washing tests were performed on the yarn containing the triazine derivative prepared in Run No. 6 of Example 5 as an antistatic agent by measuring the halflife period of the yarn.

The lwashing test is made as follows.

The yarn is formed in a bundle of 20 layers, washed with an electric washing machine for l0 minutes at 50 C. in 3% aqueous solution of commercial neutral detergent,

TABLE 9 Tenacity Amount (g./denier)/ Half-lite added (wt. elongation period percent) (percent) (SML) EXAMPLE 12 Each of triazine derivatives prepared in Run Nos. 3l, 32 and 13 of Example 5 was blended with polypropylene pellets having intrinsic viscosity of 1.8 at various blending ratios, i.e., 0.5 wt. percent, 1.0 wt. percent and 2.0 wt. percent.

Each composition obtained was spun by an ordinary melt spinning proce'ss, stretched at a drawing ratio of 3 to 4 to produce 70 denier-17 ilament polypropylene yarn.

The antistatic effect and tenacity-elongation values of each yarn are given in Table 10.

Further the washing test as described in Example 10 was performed on the yarn to demonstrate the permanency of the antistatic effect, the results given in Table 11.

TABLE 10 Triazine derivative prepared in Run No. 31

Triazine derivative pre- Triazine derivative prepared in Run No. 32

pared in Run No. 13

tr u

What is claimed is: TABLE 11 l 1. A triazine derivative represented by any one of the Ammgtfgrgmve following structural formulae 0.5 1.0 2.0 N H N H 5 RSAF/ Aim oocRsN Nmooo Times of washing Half-life period (sec.) l My; I My m 11 s 3 N N N N 20 12 7 3 50 m 14 s 3 Y Y NHRaC O O X iRs X EXAMPLE 13 and /N 'l The triazine derivative prepared 1n Example 4 was S15 w-AZ--R blended with the polyethylene powder (melt index: .2.5) 15 IL N MW at blending ratios of 0.5% by weight and 1.5% by weight, Each composition obtained was subjected to meltspinning process into 300 denier monolament. The anti- NHRBCOO px static effect and the property of it was measured and given (3) in Table 12.

wherein, A1 and A2 are same or different and each denotes a polyalkylene oxide selected from the group consisting TABLE 12 of polyethylene oxide A t t naiti; H ifiif 11191 a 8 addedlil. lonation period OCH2CH2 percent) (percent) (sec.) /n

G g gjg polypropylene oxide 1.5 4.9/25 2 --OH-Clz- EXAMPLE 14 H and ol eth lene oxideol ro lene oxide co ol mer The triazine derivative prepared in Run No. 33 of p y y p yp py p y Example 5 was blended with the polyvinylidene chloride f f (11m/c: 1.02) at various blending ratios, i.e., 0.5% by 35 TOCHZCHzj--OCHCHU weight, 1.0% by weight and 2.0% by weight. Each comm H3 position obtained was subjected to melt-spinning and then stretched UO 600 denier-15 lament yarn. wherein n is an integer of 1 to 200, m-i-n is an integer of The antistatic effect and the property of the yarn was 2 to 200, m and n are each equal to at least 1; R3 and R4 measured and given in Table 13.

are same or different and each denotes a member selected from the group consisting of alkylene of 1 to 12 carbon atoms, oand p-cyclohexylene, oand p-methylene cyclo- TABLE 13 hexylene, oand p-phenylene, and oand p-methylene Am t Tmaeit; H uw phenylene; M denotes a member selected from the group .i addediliii. (luegxatgn ario consisting of hydrogen, a metal selected from the -group Run N0 percent) (percent) (sec.) consisting of calcium, barium, magnesium, tin, aluminium, 1 0 2.3/27 copper, potassium, sodium, zinc, manganese, nickel, 2 0.5 2.0/23 t) strontium and cadmium, and an organic amine selected 1g ,135522 50 from the group consisting of mono, diand tri-ethanol amines, primary, secondary and tertiary amines of 1 to 17 carbon atoms; x and y each denotes an integer of 1 to 4 depending on the valency of the metal M; p is an integer EXAMPLE 15 of 2 to 5; R5 and R6 are same or different and each denotes a member selected from the group consisting of hydroxy,

The triazine derivative prepared 1n Run No. 33 of 55 alkoxy of 1 to 10 carbon atoms, naphthoxy, benzoxy,

Example 5 Was added t0 Polystylene PEH in 1% by secondary amino of 1 to 17 carbon atoms and weight based on the polystyrene. The composition obtained was molded into a plate having thickness of 3 mm. by -O-iI-Rz means of a conventional extrusion molder. The half-life period of the plate was measured to be 3 seconds at 20 60 C. in relative 40% RH and the antistatic effect lasted after wherein R7 denotes a member Selected from the group washing while half-life period ofthe plate not containing COHSSUg 0f hydrogen, alkyl 0f 1 t0 17 Carbon atoms, the triazine derivative is more than 1 minute. phenyl, bIlZy1 and naphhyl- 2. A triazine derivative according to claim 1, wherein EXAMPLE 16 65 said triazine derivative is represented by said structural Formula 1 wherein A1 and A2 are each polyethylene The triazine derivative obtained in Run No. 33 of oxide of n=30100, R5 and R6 are each hydroxy, R8 is Example 5 was dissolved in methylmethacrylate monomer pentamethylene and M is a member selected from the at 2% by weight based on the monomer to which was group consisting of hydrogen, Ca, Ba, Cu, Mn, monoadded benzoyl peroxide at 0.05% by weight. The mixture ethanolamine, di-ethanolamine and tri-ethanolamine. solution was heated at 60 C. for 7 hours and then at 3. A triazine derivative according to claim 1, wherein, C. for 1.5 hours to complete cast polymerization. said triazine derivative is represented by said structural The obtained polymer was extruded to form a plate Formula 2, wherein A1 is polyethylene oxide of n=30 having 3 mm. thickness. The half-life period of the plate 100, R3 and R4 are each pentamethylene, `R5 is hydroxy, was measured to be 3 sec. 75 and M is a member selected from the group consisting of 21 22 hydrogen, Ca, Ba, Cu, Mn, mono-ethanolamine, di- References Cited ethanolamine and tri-ethanolamine. l 4. A triazine derivative according to claim 1, wherein 30(1))4ui1g5g1e; al" J' Am' Chem' Soc" v01' 73 pp` 2999 said triazine derivative is represented by the structural Formula 3 wherein A1 is polyethylene oxide of 11:30- 5 JOHN M, FORD, Primary Examiner 100, R3 is pentamethylene, R5 is hydroxy, M is a member selected from the group consisting of hydrogen, Ca, Ba, U S C1 X R Cu, Mn, mono-ethanolamine, diethanolamine and triethanolamine, and pis an integer of 2-5. 8-115.6, 173; 117-1395; 252-383; 260-249.5, 249.8 

